Optimization of a multi-view display

ABSTRACT

Described herein is a multi-view display (based on spatial and/or temporal multiplexing) having an optimization mechanism that dynamically adjust views based upon detected state changes with respect to one or more views. The optimization mechanism determines viewing parameters (e.g., brightness and/or colors) for a view based upon a current position of the view, and/or on the multi-view display&#39;s capabilities. The state change may correspond to the view (a viewer&#39;s eye) moving towards another viewing zone, in which event new viewing parameters are determined, which may be in anticipation of entering the zone. Another state change corresponds to more views being needed than the display is capable of outputting, whereby one or more existing views are degraded, e.g., from 3D to 2D and/or from a personal video to a non-personal view. Conversely, a state change corresponding to excess capacity becoming available can result in enhancing a view to 3D and/or personal.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is related to the copending U.S. patentapplication entitled “Spatial and Temporal Multiplexing Display,” (U.S.patent application Ser. No. 12/819,238, now U.S. Pat. No. 10,089,937)assigned to the assignee of the present application, filed concurrentlyherewith and hereby incorporated by reference.

BACKGROUND

A multi-view display allows different images to be seen from differentpoints of view. This includes spatial multiplexing technology ordirected backlight technology, in which lenses in front of light sourcesdirect the light from illuminated pixels to different views.

In displays that use spatial multiplexing technology, increasing thenumber of views degrades the resolution of each view. In displays thatuse directed backlight technology, increasing the number of viewsreduces the frame rate for each view. Thus, one problem with amulti-view display is that the practical number of distinct views thatcan be output is limited by needing reasonable resolution to provide adecent image, or a fast enough frame rate to provide video withoutperceptible flicker. The number of views that may be needed may exceedthat practical number of distinct views.

For example, a multi-view display capable of outputting eight views canshow personal 2D video to eight people, or personal 3D video to fourpeople (one view to each eye of each person, which directed backlightingcan do without needing 3D glasses). However, if there are nine peoplewatching a 2D video, or five watching a 3D video, the multi-viewcapabilities of the display device are exceeded. Moreover, the state ofthe views may change as people move between viewing zones, leave a room,or enter a room.

SUMMARY

This Summary is provided to introduce a selection of representativeconcepts in a simplified form that are further described below in theDetailed Description. This Summary is not intended to identify keyfeatures or essential features of the claimed subject matter, nor is itintended to be used in any way that would limit the scope of the claimedsubject matter.

Briefly, various aspects of the subject matter described herein aredirected towards a technology by which a multi-view display (based onspatial and/or temporal multiplexing) is configured with an optimizationmechanism that dynamically adjust views based upon a detected statechange, e.g., by an eye tracking component. In general, the optimizationmechanism determines the viewing parameters for a view based upon acurrent position of the view, and/or on the capabilities of themulti-view display device.

In one aspect, the state change corresponds to the view (a viewer's eye)moving in one viewing zone towards another viewing zone. Theoptimization mechanism, which is associated with an anticipationalgorithm, changes the viewing parameters (e.g., brightness and/or colorvalues) according to an optimization model to new parameters for theother zone, in anticipation of the view moving into the other zone. Inthis manner, a changed view is generated for the new zone before theview moves into the new zone. In the event that another view is alreadyin the other zone, the optimization model instead computes backed offparameters for the view and the other view.

In one aspect, the state change corresponds to a need for another newview that when combined with existing views exceeds the total viewcapabilities of the device. In response, the optimization mechanismchanges the viewing parameters for the view by degrading the view, e.g.,from a personal view to a non-personal view, and/or from a 3D view(e.g., the left-eye or right eye part) to a 2D view. In the event thatexcess capability becomes available with respect to generating the totalnumber of views, the optimization mechanism may change the viewingparameters for the view by enhancing the view from a non-personal viewto a personal view, and/or from a 2D view to a 3D view.

Other advantages may become apparent from the following detaileddescription when taken in conjunction with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example and not limitedin the accompanying figures in which like reference numerals indicatesimilar elements and in which:

FIG. 1 is a block diagram representing a multiplexing system thatoptimizes views based upon view position and state changes with respectto the system.

FIG. 2 is a flow diagram representing example steps for optimizing aview based upon a state change in which the view moves towards and/orinto another viewing zone.

FIG. 3 is a flow diagram representing example steps for optimizing viewsbased on various input including a number of views desired.

DETAILED DESCRIPTION

Various aspects of the technology described herein are generallydirected towards graceful optimization in a multi-view display thatoperates to smoothly adapt to state changes with respect to one or moreviews. As used herein, a “view” may refer to one eye of a person or thesingle eye of each of a set of multiple people, such as when displayingstereoscopic (3D) video; alternatively, a view may be the same to bothof a person's eyes. Different views are generated by spatialmultiplexing (lenticular arrays, lenslets), by temporal multiplexing(directed collimated backlight), or (as described in the aforementionedU.S. patent application entitled “Spatial and Temporal MultiplexingDisplay”) by a combination of spatial and temporal multiplexing.

Thus, the number of views and the output parameters to each view (e.g.,frame rate, resolution) are dependent on the frame rate capabilities andspatial capabilities of the display device. As described herein, theviews are optimized for a current state of the system's views. Forexample, views may be optimized based upon anticipation of a spatial(viewing zone) change due to a person's movement. An anticipated spatialchange may result in computing modified display parameters (e.g.,brightness, color and so forth) for the new perspective, so that thetransition to a different viewing zone/angle is generally imperceptible.If two or more views that are otherwise independent views wind up in thesame viewing zone due to one or more person's movement, (wherebyindependent views are not able to be displayed), the different views maybe backed off (optimized for both viewers to some extent) in some way,such as smoothed together (e.g., averaged) to optimize a single,combined view for the multiple views.

Another aspect of optimization is when there are more views than thecapabilities of the display can handle. In such an event, some or all ofthe current views are degraded to accommodate the extra view or views.When there is excess capacity, some or all of the current views may beenhanced relative to their previous configuration.

It should be understood that any of the examples herein arenon-limiting. As such, the present invention is not limited to anyparticular embodiments, aspects, concepts, structures, functionalitiesor examples described herein. Rather, any of the embodiments, aspects,concepts, structures, functionalities or examples described herein arenon-limiting, and the present invention may be used in various ways thatprovide benefits and advantages in computing and video technology ingeneral.

FIG. 1 is a block diagram showing an example implementation that usesspatial or temporal multiplexing, or a combination of spatial andtemporal multiplexing, to provide a plurality of (typically) differingviews. The various components of FIG. 1 may be implemented in acomputing environment external to a display, e.g., in a computer systemor gaming console, for example, containing one or more processors andmemory to perform spatial and temporal multiplexing. Alternatively, thecomponents may be incorporated into a display device, such as atelevision set.

In the example of FIG. 1, an eye (head) tracking component 102 (e.g.,using one or more cameras and software technology) provides anoptimization mechanism (logic) 104 with the current number of views(eyes) and the position of each eye. Note that such head trackingtechnology already exists, based on known machine vision softwaretechnology, and is incorporated into gaming consoles, for example.Notwithstanding, any eye tracking technology may be used as describedherein, including technology not yet developed.

Note that the video signals may be anything, such as a single videoshot, a mix of different angles of the same 3D scene, a mix of differentvideo shots (e.g., two television programs to distribute betweendifferent viewers) and so forth. Further note that if all views are ofthe same 3D scene but some (or all) views correspond to differentviewing zones, the content (the viewing perspective) to show each viewmay be known based on the current position of that view.

As described herein, the optimization logic 104 determines how todistribute video signals 106 among the views. An optimization model 108may be accessed by an anticipation algorithm 110 to prepare a new viewif a viewer is entering into a new viewing zone, as described below.Preference rules and/or data 112 (which may be fixed defaults for agiven display device) may be accessed to determine how to distributeresources and video to the views based on the device's spatial and/ortemporal capabilities. For example, the preference rules/data 112determines how to correlate more views than can be output given thespatial and frame rate capabilities of the device, or conversely, whenless than all possible views are present, how to increase resolution andbrightness, and/or to which view or views, and so forth. Note that theoptimization logic 104 also may input (data corresponding to) the videosignals, such as to determine whether the video is 2D or 3D, and also topossibly process content-related information or other video data indetermining the distribution, e.g., to give a higher frame rate topeople watching one video with a lot of motion, and less to thosewatching another video with little motion.

Based on how the resources and video are to be distributed among theviews, the optimization logic 104 accesses the optimization model 108for each view to determine optimal parameters for each view. Theoptimization model 108 may be based upon one or more cameras thatprovide a closed feedback loop, pre-calibration, theory, and/orexperiments, and in general provides data such as brightness, color,chroma and so forth for each view. Note that the parameters may be perlight source or may be for multiple light sources (e.g., global) toprovide an optimal view according to the model for each view.

If only spatial multiplexing is available on the display device, thenthe parameters are simply output to spatial logic that divides the videoand corresponding view parameters into subsets (e.g., vertical columns)of the pixels to provide the desired number of viewing zones. Iftemporal multiplexing is available, then a scheduling algorithm uses theparameters and eye positions to determine which light sources areilluminated when, and how, e.g., their brightness and color. Similarscheduling is used when both spatial and temporal multiplexing areavailable, as described in the aforementioned U.S. patent application.In this manner, the graphics hardware 116 drives the appropriate pixelsof the multi-view display 118 to provide multiple views. This mayinclude not illuminating pixels to available views where there is noviewer present, to save energy.

In one aspect, as a view is moving towards a new zone, the anticipationalgorithm 110 (e.g., based upon or incorporating a Kalman filter) canprepare that view for the transition. For example, when a view is movingbetween spatial zones, the fine control of the directed backlight may beused to generate a new lensed view for the new zone (with parameters forthe new viewing perspective), and once the person reaches the end of alenticular zone, switch to the new lensed zone view. Using theoptimization model 108 to determine new parameters, the switch may bemade imperceptible to the eye.

FIG. 2 shows example logic for anticipating the change to a new (e.g.,spatial) zone, beginning at step 202 which represents waiting for a viewto be detected as moving to a new zone, e.g., based on the eye trackingposition and known zone positions. Note that step 202 may be eventdriven (rather than looping back and waiting as illustrated forsimplicity).

Step 204 represents the optimization logic 104 accessing theoptimization model 108 to determine optimal parameters (e.g.,brightness, color data and so forth) for the new zone. Note that even ifthe content being viewed is relatively static, the parameters may needto change because different lenses, distances and so forth apply to thenew zone or directed backlight steered photons to the anticipatedposition.

Step 206 represents determining whether another view is already in thatzone, as described below. If not, then the anticipated parameters forthe view that were computed/determined may be output (step 208) to thenext zone or position in advance. If the eye enters that zone, the viewis already present with the appropriate parameters such that thetransition is generally imperceptible. Note, however, that analternative is to have former zone parameters, transition parameters andnew zone parameters. For example, if a view is transitioning betweenzones, then the parameters (e.g., brightness/colors) of the former zoneand the parameters of the new zone may be combined (e.g., via anappropriate function) according to the model 108 so that an eyecorresponding to the view does not get too much brightness/impropercolors just as the view crosses the zone dividing line.

Returning to step 206, it is possible that a view is entering a new zonethat already has another, different view (or views) being shown.Consider for example that the right eye of person A enters a zone thatperson B is already within, viewing video frames. If directed backlighttechnology is unavailable to provide separate views within the spatialzone, or if the alignment is such that the right eye of person A isaligned with the left eye of person B and directed backlight is onlyable to collimate the light horizontally (not vertically), then aconflict exists.

Step 210 represents resolving the conflict by computing backed offparameters for the views, that is, the parameters are optimized formultiple views to some extent. For example, the parameters may beaveraged or otherwise blended/smoothed for two or more views. This maywork up to some number of different views, however if too many views arepresent, then the optimization logic 104 may instead degrade the devicesuch that all the views in the zone are the same. For example, asdescribed below, instead of personal 3D video where each person gets hisor her own view based on their relative position to a scene, theoptimization logic 104 may back off the views to non-personal 3D, or 2Dfor some or all of the viewers. The optimization logic 104 may choose tonot show a view, such as if two different television programscorresponding to different views are being watched; the person enteringthe new view and causing the conflict may see nothing or may be switchedto the view of the person that was already viewing in that zone.

As represented by steps 212 and 214, applying the backed off parametersmay wait until the person actually enters the new zone. In this manner,for example, a person already in the zone does not receive a degradedview until necessary. However, some transitioning parameters/functionmay be applied to make the transition to the backed off parametersgradual, e.g., within the current zone at some approaching distance tothe new zone, the backed off parameters are computed. As the distancegets closer, a transition function gradually adjusts the current zoneparameter values (e.g., more towards the backed off parameter values) sothat when the person does enter the zone and the backed off parametersare fully applied, the change is less perceptible to the existing viewerand/or the newly entering viewer.

Another aspect of optimization is directed towards correlating thespatial and/or temporal capabilities of the device with the number ofviews. For example, when the resolution capacity of a system isexceeded, the optimization logic 104 (e.g., in combination with theoptimization model 108 and/or preference rules/data 112) needs todetermine how to optimize the views.

By way of example, consider a desired offering of multiple personal 3Dviews, that is, a private or personal view may be a view that is visibleto a person in one location and not visible to a person at anotherlocation. A 3D view may be a view that provides a different view to theleft and right eye of a user to give the user a sense that the view isthree dimensional. Even using the above described multi-view display,the capacity of the display device may be unable generate a sufficientnumber of (visually acceptable) personal 3D views for the number ofviewers.

Various optimization options are available when the capacity isexceeded, generally comprising degrading one or more of the views toaccommodate the number needed. Note that degradation may be dynamic,e.g., when a new viewer enters a room and starts looking at the display,the optimization logic 204 recognizes whenever the capacity is exceeded.For example, if the optimization logic 204 recognizes that the displaydevice cannot support giving a personal 3D view to the new person, thedisplay device may take a number of options, e.g., depending on thepreference rules data 112 and what capacity is available. Further notethat degradation may not be immediate, e.g., simply because a person ispassing through a room and glances at the head tracking camera does notmean that existing viewers have their views degraded; degradation toaccommodate the new person may be deferred until it is more certain thatthe new person is actually there to see the display.

By way of an example, the device may not have the capability to give thepersonal 3D view to the new person, but may have one view left via whichthe new person may receive a flat 2D picture. As a more particularexample, if a display device is capable of outputting nine distinctviews (e.g., three spatial times three temporal), four people may bereceiving personal 3D video, thereby using eight of the nine possibleviews. The ninth view thus may be used to output 2D to the new person,as well to as any other person that enters later. For example, this maybe accomplished by displaying 2D to all positions (zones and angles)except to those specific eye positions of the four personal 3D viewers.

Another option (when two views are available) is to provide non-personal2D or 3D to one or more viewers, while other people get personal 3D or2D. For example, consider that two views are available however two newpeople enter a room and look at the display. Each may receive personal2D views (both of each person's eyes get the same view but each persongets a different view). Alternatively, non-personal 3D views may bepresented.

If less than the number of views needed is available, one or moreexisting views need to be degraded as well. For example, if a largenumber of viewers enter a room, the system may degrade the views so thateveryone gets a non-personal 2D view. As can be appreciated, variousother techniques can also be used, e.g., degrade all but a privileged(view or views), degrade in time order (last person to start viewing isthe first one degraded, and so forth). Other options include choosingthe view based on the person/people sitting closest to the display,sitting closest to the center of the display, to the person who istalking the most or presently talking, to the person/people presentlylooking (e.g., based on gaze tracking), and so forth.

In contrast to degrading, enhancing the views relative to their previousstate (e.g. 2D to 3D/non-personal to personal) is also possible, such aswhen one or more existing viewers leave the room, causing excesscapacity. In general, the same alternatives exist for degradation as towhich view (or views) is to be enhanced, and how each such view is to beenhanced.

FIG. 3 shows some example steps that may be performed by theoptimization logic 204, beginning at step 302 where the number of eyes(maximum possible views desired) is received from the head trackingcomponent. At step 304, the optimization logic 204 computes how manyviews are needed based upon the number of views and the 2D and/or 3Dnature of the video signals 206.

As represented by step 306 and as described above, the preferencerules/data 112 (and or the optimization model) 108 may be consulted todetermine what to do when there is an inexact match between the viewsneeded versus those that can be independently generated, e.g., whichview or views are to be degraded (e.g., combined) or enhanced accordingto the preference data 208, given the current number of possible views.Content-based throttling or enhancement may also be performed, e.g.,based on how the preference data specifies that current motioninformation be used, as also described above.

In general, via step 308 the scheduling algorithm 114 receives thesecomputed/determined parameters from the optimization logic 104. Forexample, parameters may include an identifier for each view, and thetype of output for that view, e.g., personal 3D, personal 2D,non-personal 3D or non-personal 2D. With this information and theposition data for each distinct view, the scheduling algorithm 114 thendetermines the pixels to illuminate (including at what specific timesfor temporal multiplexing).

While the invention is susceptible to various modifications andalternative constructions, certain illustrated embodiments thereof areshown in the drawings and have been described above in detail. It shouldbe understood, however, that there is no intention to limit theinvention to the specific forms disclosed, but on the contrary, theintention is to cover all modifications, alternative constructions, andequivalents falling within the spirit and scope of the invention.

What is claimed is:
 1. A method comprising: determining a number ofcurrent viewers of a multi-view display, the multi-view display beingcapable of providing a limited number of views that is limited by bothspatial multiplexing capabilities and temporal multiplexing capabilitiesof the multi-view display; determining particular times at which toilluminate individual light sources of the multi-view display totemporally multiplex three-dimensional video for the current viewers;detecting presence of a new viewer of the multi-view display, whereinproviding three-dimensional video to the current viewers and the newviewer would require more views than the multi-view display is capableof providing; responsive to detecting the presence of the new viewer ofthe multi-view display: selecting a particular current viewer fordegrading to two-dimensional video via temporal multiplexing whileproviding three-dimensional video to other current viewers, theparticular current viewer being selected for degrading based on theother current viewers being relatively closer to the multi-view displaythan the particular current viewer that is selected for degrading; anddegrading the particular current viewer of the multi-view display totwo-dimensional video while continuing to provide three-dimensionalvideo to the other current viewers, the degrading comprising adjustingthe particular times at which the individual light sources areilluminated.
 2. The method of claim 1, further comprising: identifying aspecific privileged viewer that is designated to receivethree-dimensional video; and preventing the specific privileged viewerfrom being degraded to two-dimensional video when the presence of thenew viewer is detected.
 3. The method of claim 1, wherein thethree-dimensional video comprises personal three-dimensional video. 4.The method of claim 1, wherein the degrading comprises adjusting spatialmultiplexing of the multi-view display.
 5. The method of claim 1,wherein the particular current viewer is degraded from personalthree-dimensional video to personal two-dimensional video.
 6. The methodof claim 5, wherein the personal two-dimensional video is visible to theparticular current viewer of the multi-view display and not visible toat least one other current viewer of the multi-view display.
 7. Themethod of claim 1, wherein the limited number of views is based on aspecified minimum resolution, specified minimum frame rate, or both. 8.A system comprising: a multi-view display device; and logic configuredto: determine a number of current viewers of the multi-view displaydevice, the multi-view display device being capable of providing alimited number of views that is limited by both spatial multiplexingcapabilities and temporal multiplexing capabilities of the multi-viewdisplay device; determine particular times at which to illuminateindividual light sources of the multi-view display device to temporallymultiplex three-dimensional video for the current viewers; detectpresence of a new viewer of the multi-view display device, whereinproviding three-dimensional video to the current viewers and the newviewer would require more views than the multi-view display device iscapable of providing; responsive to detecting the presence of the newviewer of the multi-view display device: select a particular currentviewer for degrading to two-dimensional video via temporal multiplexingwhile providing three-dimensional video to other current viewers, theparticular current viewer being selected for degrading based on theother current viewers being relatively closer to the multi-view displaydevice than the particular current viewer that is selected fordegrading; and degrade the particular current viewer of the multi-viewdisplay device to two-dimensional video while continuing to providethree-dimensional video to the other current viewers, the degradingcomprising adjusting the particular times at which the individual lightsources are illuminated.
 9. The system of claim 8, further comprising adirected collimated backlight comprising the individual light sources.10. The system of claim 8, wherein the logic is further configured to:provide at least one of the other current viewers with personalthree-dimensional video that is not visible to remaining current viewersof the multi-view display device.
 11. The system of claim 10, whereinthe two-dimensional video provided to the particular current viewer isnot visible to the other current viewers of the multi-view displaydevice.
 12. The system of claim 8, wherein the logic is furtherconfigured to: after detection of the new viewer, delay degradation ofthe particular current viewer until confirmation that the new viewer isactually viewing the multi-view display device.
 13. The system of claim8, wherein the limited number of views is nine.
 14. The system of claim13, wherein the multi-view display device has threespatially-multiplexed views and three temporally-multiplexed viewsusable together to provide the limited number of nine views.
 15. Asystem comprising: a multi-view display device; a processor; and logicwhich, when executed by the processor, causes the system to: determine anumber of current viewers of the multi-view display device, themulti-view display device being capable of providing a limited number ofviews that is limited by both spatial multiplexing capabilities andtemporal multiplexing capabilities of the multi-view display device;determine particular times at which to illuminate individual lightsources of the multi-view display device to temporally multiplexthree-dimensional video for the current viewers; detect presence of anew viewer of the multi-view display device, wherein providingthree-dimensional video to the current viewers and the new viewer wouldrequire more views than the multi-view display device is capable ofproviding; responsive to detecting the presence of the new viewer of themulti-view display device: select a particular current viewer fordegrading to two-dimensional video via temporal multiplexing whileproviding three-dimensional video to other current viewers, theparticular current viewer being selected for degrading based on theother current viewers being relatively closer to the multi-view displaydevice than the particular current viewer that is selected fordegrading; and degrade the particular current viewer of the multi-viewdisplay device to two-dimensional video while continuing to providethree-dimensional video to the other current viewers, the degradingcomprising adjusting the particular times at which the individual lightsources are illuminated.
 16. The system of claim 15, further comprising:an eye tracking component configured to track the new viewer and thecurrent viewers.
 17. The system of claim 15, wherein the logic, whenexecuted by the processor, causes the system to: identify a specificprivileged viewer that is designated to receive three-dimensional video;and prevent the specific privileged viewer from being degraded totwo-dimensional video when the presence of the new viewer is detected.18. The system of claim 15, wherein the multi-view display device hasthree spatially-multiplexed views and three temporally-multiplexed viewsusable together to provide nine views as the limited number.
 19. Thesystem of claim 18, wherein there are four current viewers of themulti-view display device when the new viewer is detected and theparticular current viewer is degraded from three-dimensional video totwo-dimensional video.
 20. The system of claim 15, wherein the newviewer is provided three-dimensional video based at least on the newviewer being relatively closer to the multi-view display device than theparticular current viewer that is degraded to two-dimensional video.